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1	Planting Dates for Small Grains in Arizona Ottman, Michael 03 1900 (has links) 3 pp. / The optimum planting by elevation is presented for small grains in Arizona. The influence of planting date on crop development, grain yield and frost risk is discussed. Grain yield crop development frost wheat barley durum
2	Inheritance of erucic acid in <i>brassica carinata</i> a braun and development of low glucosinolate lines Alemaw, Getinet 01 January 1996 (has links) <p>Ethiopian mustard (<i>Brassica carinata</i> A. Braun) or gomenzer is an oilseed crop that is well adapted to the highlands of Ethiopia. Evaluation of the local germplasm has resulted in the registration of high yielding cultivars, such as Dodolla and S-67. The oil of gomenzer contains about 40% erucic acid and the meal is high in glucosinolates. The objective of this research was to study the inheritance of erucic acid content in gomenzer and to introgress genes for the non2-propenyl glucosinolate trait from <i>B. napus</i> and <i>B. juncea</i>. The erucic acid content of F<sub>1</sub> seed from reciprocal crosses between the high erucic acid cultivars Dodolla and S-67 and zero erucic acid line C90-14 was intermediate between the parents indicating that erucic acid content in B. carinata was controlled by two nondominant genes with two alleles acting in an additive manner. Backcross F<sub>1</sub> seed derived from the backcross to the low erucic acid parent fell into three erucic acid classes with $<$0.5%, 6 to 16% and $>$16% erucic acid at the ratio of 1:2:1 indicating that erucic acid was under the control of two alleles each of at two loci. F<sub>2</sub> seed segregation data supported this observation. Each allele contributed approximately 10% erucic acid. The high glucosinolate B. carinata line C90-14, low glucosinolate <i>B. napus</i> cultivar Westar and <i>B. juncea</i> line J90-4253 were chosen as parents for the development of non2-propenyl glucosinolate <i>B. carinata</i>. The objective was to transfer genes for non2-propenyl glucosinolate content from <i>B. napus</i> and <i>B. juncea</i> into <i>B. carinata.</i> Interspecific crosses were made between <i>B. carinata</i> and <i>B. napus</i>, <i>B. carinata</i> and <i>B. juncea</i> and the interspecific F<sub>1</sub> generations were backcrossed to <i>B. carinata</i>. Backcross F<sub>1</sub> plants from the two interspecific crosses were intercrossed in an attempt to combine the two sources for non2-propenyl glucosinolate content in one genotype. Seed of backcross F<sub>1</sub> plants of the cropss ((<i>B. carinata</i> x <i>B. napus</i>) x <i>B. carinata</i>) contained a high concentration of 2-propenyl glucosinolate similar to those of <i>B. carinata</i>. Introgression of C genome chromosomes of <i>B. napus</i> into <i>B. carinata</i> was not effective in redirecting glucosinolate synthesis away from 2-propenyl and into 3-butenyl glucosinolate. This indicated that C genome chromosomes do not contain genetic factors for C3 $\to$ C4 glucosinolate precursor chain elongation, and that 2-propenyl glucosinolate synthesis is primarily controlled by genes on B genome chromosomes. Seed of ackcross F<sub>2</sub> plants of the cross ((<i>B. carinata</i> x <i>B. juncea</i>) x <i>B. carinata</i>) contained much reduced levels of 2-propenyl glucosinolate indicating that genetic factors for C3 $\to$ C4 glucosinolate precursor chain elongation were introgressed from the B genome of <i>B. juncea</i> into the B genome of <i>B. carinata</i>. However, a complete diversion of glucosinolate synthesis from 2-propenyl to 3-butenyl was not achieved. Further selections in segregating F<sub>4</sub> and F<sub>5</sub> generations of <i>B. juncea</i> derived <i>B. carinata</i> populations could yield the desired zero 2-propenyl glucosinolate B. carinata. The double interspecific cross was unsuccessful. crop science crop development plant genetics Ethiopian mustard oilseed
3	Modeling and Predicting Wheat Phenological Development Using Meteorological Information / 気象情報を利用したコムギの発育のモデル化と予測 Kawakita, Satoshi 23 September 2020 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(情報学) / 甲第22802号 / 情博第732号 / 新制\|\|情\|\|125(附属図書館) / 京都大学大学院情報学研究科社会情報学専攻 / (主査)教授守屋和幸, 教授大手信人, 教授河原達也 / 学位規則第4条第1項該当 / Doctor of Informatics / Kyoto University / DGAM Crop development model Meteorology Parameterization Prediction Wheat phenology 007
4	Improved Tomato Grafting Technologies Hu, Bizhen January 2016 (has links) No description available. Horticulture
5	Heat Units Brown, Paul W. 07 1900 (has links) 7 pp. Heat Units Growing Degree Days Temperature Phenology Pest Management Crop Management Crop Development

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